Utilization of Bottom Ash from Power Plants as Backfill Material for Surface Coal Mines with Enhanced Carbon Dioxide Capture and Storage Capabilities

Article Sidebar

pdf
Published: Jan 16, 2026
DOI: https://doi.org/10.55003/cast.2026.267791
Keywords:
bottom ash mine backfill material CO2 absorption waste utilization lignite byproducts surface coal mines

Main Article Content

Pintunicha Pongsena
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Matika Buaphian
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Nutdanai Srisuk
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Bunlang Mansanit
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Manoon Masniyom
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Matthana Khangkhamano
Department of Mining and Materials Engineering, Faculty of Engineering, Prince of Songkla University, Songkhla, Thailand
Naruemol Saoanunt
In response to the growing need for sustainable mine reclamation, this study investigates the use of bottom ash, a byproduct of coal or lignite combustion, as a component in backfill materials for surface mining. The study focuses on evaluating the CO2 absorption capacity and mechanical strength properties of mixtures containing varying ratios of bottom ash and smectite. Composite backfill material strength was assessed through unconfined compressive strength (UCS) and direct shear tests. The mixture with a bottom ash to smectite ratio of 30:70 exhibited the highest UCS across all moisture levels, with a peak value of 139 kPa at 10% water content. At this condition, the mixture also showed a cohesion of 17.06 kPa, an internal friction angle of 31.2°, and a shear strength of 25.32 kPa. Based on these results, samples at 10% water content were selected for CO2 absorption testing across different bottom ash–smectite ratios. The 10:90 ratio demonstrated the highest CO2 absorption capacity at 3.16 mg/g, with a decreasing trend observed as the proportion of bottom ash increased. These findings suggest that bottom ash–smectite mixtures can be optimized to achieve both pit wall stability and enhanced carbon sequestration, supporting their use as sustainable backfill materials in mine reclamation.

Abstract

In response to the growing need for sustainable mine reclamation, this study investigates the use of bottom ash, a byproduct of coal or lignite combustion, as a component in backfill materials for surface mining. The study focuses on evaluating the CO2 absorption capacity and mechanical strength properties of mixtures containing varying ratios of bottom ash and smectite. Composite backfill material strength was assessed through unconfined compressive strength (UCS) and direct shear tests. The mixture with a bottom ash to smectite ratio of 30:70 exhibited the highest UCS across all moisture levels, with a peak value of 139 kPa at 10% water content. At this condition, the mixture also showed a cohesion of 17.06 kPa, an internal friction angle of 31.2°, and a shear strength of 25.32 kPa. Based on these results, samples at 10% water content were selected for CO2 absorption testing across different bottom ash–smectite ratios. The 10:90 ratio demonstrated the highest CO2 absorption capacity at 3.16 mg/g, with a decreasing trend observed as the proportion of bottom ash increased. These findings suggest that bottom ash–smectite mixtures can be optimized to achieve both pit wall stability and enhanced carbon sequestration, supporting their use as sustainable backfill materials in mine reclamation.

Article Details

How to Cite
Pongsena, P., Buaphian, M., Srisuk, N. ., Mansanit, B. ., Masniyom, M. ., Khangkhamano, . M., & Saoanunt, N. (2026). Utilization of Bottom Ash from Power Plants as Backfill Material for Surface Coal Mines with Enhanced Carbon Dioxide Capture and Storage Capabilities. CURRENT APPLIED SCIENCE AND TECHNOLOGY, e0267791. https://doi.org/10.55003/cast.2026.267791
Issue
Online First Articles
Section
Original Research Articles
Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Copyright Transfer Statement

 The copyright of this article is transferred to Current Applied Science and Technology journal with effect if and when the article is accepted for publication. The copyright transfer covers the exclusive right to reproduce and distribute the article, including reprints, translations, photographic reproductions, electronic form (offline, online) or any other reproductions of similar nature.

 The author warrants that this contribution is original and that he/she has full power to make this grant. The author signs for and accepts responsibility for releasing this material on behalf of any and all co-authors.

Here is the link for download: Copyright transfer form.pdf

 

 

Crossref
Scopus
Google Scholar
Europe PMC

References

Ardit, M., Cruciani, G., & Dondi, M. (2012). Local structural relaxation around Co²⁺ along the hardystonite–Co-åkermanite melilite solid solution. Physics and Chemistry of Minerals, 39(9), 713-723. https://doi.org/10.1007/s00269-012-0525-9

ASTM. (2007). Standard test method for particle-size analysis of soils (ASTM D422-63). ASTM International. https://doi.org/10.1520/D0422-63R07

ASTM. (2010a). Standard test method for unconfined compressive strength of cohesive soil (ASTM D2166-06). ASTM International. https://doi.org/10.1520/D2166-06

ASTM. (2010b). Standard practice for classification of soils for engineering purposes (Unified Soil Classification System) (ASTM D2487-06). ASTM International. https://doi.org/10.1520/D2487-06

ASTM. (2017). Standard test method for laboratory determination of water (moisture) content of soil and rock by mass (ASTM D2216-98). ASTM International. https://doi.org/10.1520/D2216-98

ASTM. (2020). Standard test method for direct shear test of soils under consolidated drained conditions (ASTM D3080-11). ASTM International. https://doi.org/10.1520/D3080_D3080M-11

ASTM. (2021). Standard test methods for laboratory compaction characteristics of soil using standard effort (ASTM D698-12). ASTM International. https://doi.org/10.1520/D0698-12R21

ASTM. (2023). Standard test method for relative density (specific gravity) and absorption of fine aggregate (ASTM C128-22). ASTM International. https://doi.org/10.1520/C0128-22

Câmara, J. G. D. A., Fraga, T. J. M., Baptisttella, A. M. S., de Araujo, C. M. B., Ferreira, J. M., Sobrinho, M. A. D. M., & de Abreu, C. A. M. (2023). Removal of BTEX and heavy metals from wastewater by modified smectite clays: ion exchange and adsorption mechanisms. Chemical Papers, 77, 5519-5529. https://doi.org/10.1007/s11696-023-02882-5

Chouikhi, N., Cecilia, J. A., Vilarrasa-García, E., Besghaier, S., Chlendi, M., Duro, F. I. F., Castellon, E. R., & Bagane, M. (2019). CO2 adsorption of materials synthesized from clay minerals: A review. Minerals, 9(9), Article 514. https://doi.org/10.3390/min9090514

Franco, F., Cecilia, J. A., Pardo, L., Essih, S., Pozo, M., dos Santos-Gómez, L., & Colodrero, R. M. P. (2024). Reversed Mg-based smectites: A new approach for CO₂ adsorption. Nanomaterials, 14(18), Article 1532. https://doi.org/10.3390/nano14181532

Fujikawa, T., Sato, K., Koga, C., Sakanakura, H., Kubota, H., & Nagayama, Y. (2019). Geotechnical characteristics of carbonated incineration bottom ash using exhaust and CO2 from waste incineration facilities. Japanese Geotechnical Society Special Publication, 9(4), 130-135. https://doi.org/10.3208/jgssp.v09.cpeg132

Götze, J., & Möckel, R. (2012). Quartz: Deposits, mineralogy and analytics. Springer. https://doi.org/10.1007/978-3-642-22161-3

Grekov, D. I., Suzuki-Muresan, T., Kalinichev, G. A., Pré, P., & Grambow, B. (2020). Thermodynamic data of adsorption reveal the entry of CH₄ and CO₂ in a smectite clay interlayer. Physical Chemistry Chemical Physics, 22(29), 16727-16733. https://doi.org/10.1039/D0CP02135K

Ingold, P., Weibel, G., Wanner, C., Gimmi, T., & Churakov, S. V. (2024). Hydrological and geochemical properties of bottom ash landfills. Environmental Earth Sciences, 83, Article 180. https://doi.org/10.1007/s12665-024-11471-y

Jiarawattananon, M., Wasanapiarnpong, T., & Mongkolkachit, J. (2019). Utilization of lignite bottom ash as a raw material for ceramic tile. Journal of Metals, Materials and Minerals, 29(4), 23-27. https://doi.org/10.14456/jmmm.2019.43

Kim, H.-J., & Lee, H.-K. (2017). Mineral sequestration of carbon dioxide in circulating fluidized bed combustion boiler bottom ash. Minerals, 7(12), Article 237. https://doi.org/10.3390/min7120237

Ksaibati, K., & Sayiri, S. R. K. (2006). Utilization of Wyoming bottom ash in asphalt mixes. https://www.ugpti.org/resources/reports/downloads/mpc06-179.pdf

Levien, L., Weidner, D. J., & Prewitt, C. T. (1979). Elasticity of diopside. Physics and Chemistry of Minerals, 4, 105-113. https://doi.org/10.1007/BF00307555

Mendel, N. (2024). Smectite-rich clays for CO₂ adsorption and separation [Doctoral dissertation, University of Twente]. https://doi.org/10.3990/1.9789036562119

Michels, L., Fossum, J. O., Rozynek, Z., Hemmen, H., Rustenberg, K., Sobas, P. A., Kalantzopoulos, G. N., Knudsen, K. D., Janek, M., Plivelic, T. S., & da Silva, G. J. (2015). Intercalation and retention of carbon dioxide in a smectite clay promoted by interlayer cations. Scientific Reports, 5, Article 8775. https://doi.org/10.1038/srep08775

Pipatmanomai, S., Fungtammasan, B., & Bhattacharya, S. (2009) Characteristics and composition of lignites and boiler ashes and their relation to slagging: The case of Mae Moh PCC boilers. Fuel, 88(1), 116-123. https://doi.org/10.1016/j.fuel.2008.08.007

Power, M. C. (1953). A new roundness scale for sedimentary particles. Journal of Sedimentary Petrology, 23(2), 117-119. https://doi.org/10.1306/D4269567-2B26-11D7-8648000102C1865D

Pusch, R., & Yong, R. N. (2006). Microstructure of smectite clays and engineering performance. CRC Press. https://doi.org/10.1201/9781482265675

Scherb, S., Maier, M., Mathias, K., Beuntner, N., & Thienel, K. (2024). Reaction kinetics of calcined smectite in a clinker-free model and a synthetic cement system in comparison with selected calcined phyllosilicates. Cement and Concrete Research, 189, Article 10776. https://doi.org/10.1016/j.cemconres.2024.107766

Siddique, R. (2008). Waste materials and by-products in concrete. Springer. https://doi.org/10.1007/978-3-540-74294-4

Singh, M., & Siddique, R. (2013). Effect of coal bottom ash as partial replacement of sand on properties of concrete. Resources, Conservation and Recycling, 72, 20-32. https://doi.org/10.1016/j.resconrec.2012.12.006

Vishwakarma, K., & Shukla, S. (2024). Bottom ash production, utilization, disposal, and its impact on the environment: A review of state-of-the-art. In G. L. Sivakumar Babu, R. H. Mulangi, & S. Kolathayar (Eds.). Technologies for sustainable transportation infrastructures (Vol. 529, pp. 393-406). Springer Nature Singapore. https://doi.org/10.1007/978-981-97-4852-5_31

Wang, P., Shen, X., Qiu, S., Zhang, L., Ma, Y., & Liang, J. (2024). Clay-based materials for heavy metals adsorption: Mechanisms, advancements, and future prospects in environmental remediation. Crystals, 14(12), Article 1046. https://doi.org/10.3390/cryst14121046

War, K., Raveendran, G., Roy, S. & Arnepalli, D. N. (2023). Effect of CO2–clay interaction on swelling stress generation capacity and porosity of clay-rich medium. In Proceedings of the 9th International Congress on Environmental Geotechnics (pp. 352-360). https://doi.org/10.53243/ICEG2023-193